DE1248339B - Adjustable allocator in matrix form - Google Patents

Description

Adjustable Allocator in Matrix Form The invention relates to a adjustable assigner in matrix form, the linking elements of which correspond to the desired assignment of input and output lines can be controlled.

Compared to conventional Assigners have the advantage that they are not switched for a new purpose needs to become. It is only necessary on the input and output lines to create successively the information assigned to one another, whereby the Form the connection points in the matrix accordingly.

The allocator according to the invention is characterized in that the Crossing points of the matrix electrolytic collector cells as connecting elements are provided when setting the allocator via the input and output lines of the matrix are charged and which serve as power sources when assigning.

With this allocator, learning matrices can be easily implemented, whereby during the learning process the electrolytic collector cells are connected to the corresponding Link points are charged and in the optional phase the learned assignment of input and output signals is available.

Further developments of the subject matter of the invention are in the subclaims marked.

The subject matter of the invention will now be explained with reference to FIGS. 1 and 2 for example explained in more detail. It shows F i g. 1 the circuit diagram of the allocator, FIG. 2 one special advantageous embodiment of a connection point of the matrix.

In FIG. 1 shows a decoding circuit for two input variables X1 and X 2 as an exemplary embodiment. The input variables X 1 and X 2 are represented by the positions of switches S1 and S2. A binary "0" means that the corresponding switch, as shown, is in the right switch position, while a binary "1" means that the switch is in the left switch position.

In the Zuordnermatrix M a respective combination element 11 ... 44 are provided at each intersection, each consisting of an electrolytic cell collector A and a resistor R. Changeover switches S3 ... S6 are connected to the output lines y 1 ... y 4 and can be switched depending on the function of the adjustable allocator that has just been carried out.

The switches S3 ... S6 are initially in the learning phase ih switch position b. The electrolytic collector cells A of the linking matrix M are discharged in the idle state of the allocator or are previously discharged by a short-circuit device (not shown here). Should z. If, for example, the output line b 1 is marked for the input information 00 (as shown in FIG. 1), the switches S1 and S2 are both switched to the right according to the binary meaning 00 and the switch S3 belonging to the output b 1 in the position c switched.

The other switches S4. . . S6 remain in position b. In this switch position, the electrolytic collector cells of the linking elements 21 and 41 are charged by the direct voltage Ub.

Since there are four different combination options for two input variables X 1 and X 2 , the three remaining combinations can also be set. If, for example, output b 2 is to be marked for input information O1, switch S1 is switched to the right, switch S2 to the left and switch S4 to position c to set the assigner. The switches S3, SS and S6 remain in position b. As a result of these switch positions, the electrolytic collector cells 22 and 32 are now charged in addition to the electrolytic collector cells 21 and 41 that were charged first. The remaining two code combinations can be set in the allocator in the same way.

In the optional phase of the assigner, all switches S3. . . S6 switched to position a. In this switching position, the output lines y 1 ... Y 4 of the matrix 111 are connected to the inputs of a circuit E for determining extreme values. This circuit E has four outputs b 1 ... b4, of which the one whose input carries the greatest signal is marked. In the manner described above, the following assignment can, for example, have been achieved: 00 corresponds to bl, 0l corresponds to b2, 10 corresponds to b3, 11 corresponds to b4. Accordingly, the electrolytic collector cells 21, 41, 22, 32, 13, 43, 14 and 34 have been charged.

If the switches S1 and S2 are in the position shown in FIG. 1, the following current components are now applied to the output lines of the matrix M: y 1 = two components, y 2 = one component, y 3 = one component. y 4 = no share. The extreme value circuit E thus marks the output line b 1.

All types can be used as electrolytic collector cells A, which can be charged by brief setting signals and their charge for a longer period Keep time. Nickel-iron accumulators were used in the exemplary embodiment.

So that the linking elements 11. . . 44 in the optional phase, ie in the function as a set allocator, act as current sources so that the currents on the output lines y 1 ... Y 4 add up accordingly, resistors R are connected upstream of the electrolytic collector cells A. It is also possible to use a corresponding type of accumulator with a sufficiently high internal resistance while eliminating the resistors R.

A particularly advantageous embodiment is shown in FIG. 2 shown. Here the electrolytic collector cell A is also preceded by a resistor R, which, however, is bridged with a diode D. When charging the electrolytic Collector cell, d. H. During the setting process of the allocator, the diode D conductive and bridges the resistor R. This can charge the corresponding electrolytic collector cells take place faster than it is via a series resistor R would be possible. During the unloading process, i. H. with the allocator function, the diode is D blocked, and the link element acts via the unbridged series resistor R.

Of course, the electrolytic collector cells will be yours Gradually hand over charges when assigning. However, if you choose those for an assignment process removed load is low compared to the load quantity, so the allocator can consider proportionately be used for a long time and relatively often. However, it is also conceivable after a certain drop in the charge through the individual linking elements again To regenerate recharge.

Claims (9)

Claims: 1. Adjustable allocator in matrix form, characterized in that electrolytic collector cells (A) are provided as linking elements at the intersection points of the matrix (M), which when setting the allocator via the input (X1, XI, X2, X2) and output lines (y 1 ... y 4) of the matrix are charged and which serve as current sources during assignment. 2. Allocator according to claim 1, characterized in that as a linking element Serving electrolytic collector cells (A) have high internal resistance. 3. Allocator according to Claim 1, characterized in that each is used as a linking element The electrolytic collector cell (A) used is preceded by an ohmic resistor (R) is. . 4. Allocator according to claim 3, characterized in that the in series with the electrolytic collector cell (A) lying resistor (R) a diode (D) in parallel is connected to the charging direction of the electrolytic collector cell in passage is polarized. 5. Allocator according to claim 4, characterized in that the parallel connection from diode (D) and resistor (R) through a diode with constant finite blocking resistance is replaced. 6. Allocator according to claims 1 to 5, characterized in that the inputs (X1 ... X2) of the matrix via several first switches (S1, S2) with the first pole (-I- Ub) and the outputs (y 1 ... y 4) of the matrix via several second switches (S3 ... S6) are connected to the second pole (- Ub) of a DC voltage source (Ub) and that these switches (S1 ... S6) correspond to the desired assignment of Input and output information for setting the assigner can be actuated. 7. Allocator according to claim 6, characterized in that when allocating the first switches (S1, S2) located at the input of the matrix can be actuated according to the information applied and that the current in the output lines (y 1 ... y 4) of the matrix serves as the initial criterion for the assigner. B. Allocator according to Claim 7, characterized in that the output lines (y 1 ... y4) of the matrix (M) are connected to the outputs (b 1 ... b 4) of the allocator via at least one circuit for determining extreme values (E). 9. Decoding circuit according to one or more of claims 1 to 8, characterized in that the input side (X1, XI, X2, X2) of the matrix is carried out adversely and is controlled via first switches (S1, S2) according to the input information and that the Output lines (y 1 ... y 4) of the matrix (M) are connected to the outputs (b 1 ... b 4) of the allocator via a circuit for determining extreme values (E). Documents considered: German Auslegeschrift No. 1069 405; French Patent No. 1278 636; New technology in the office, 1962, issue 1, pp. 5 to 11.